mathe/Library/PackageCache/com.unity.shadergraph@14.0.8/ShaderGraphLibrary/GeometricTools.hlsl
2024-09-20 20:30:10 +02:00

174 lines
6.6 KiB
HLSL

#ifndef UNITY_GEOMETRICTOOLS_INCLUDED
#define UNITY_GEOMETRICTOOLS_INCLUDED
//-----------------------------------------------------------------------------
// Intersection functions
//-----------------------------------------------------------------------------
// return furthest near intersection in x and closest far intersection in y
// if (intersections.y > intersections.x) the ray hit the box, else it miss it
// Assume dir is normalize
float2 BoxRayIntersect(float3 start, float3 dir, float3 boxMin, float3 boxMax)
{
float3 invDir = 1.0 / dir;
// Find the ray intersection with box plane
float3 firstPlaneIntersect = (boxMin - start) * invDir;
float3 secondPlaneIntersect = (boxMax - start) * invDir;
// Get the closest/furthest of these intersections along the ray (Ok because x/0 give +inf and -x/0 give -inf )
float3 closestPlane = min(firstPlaneIntersect, secondPlaneIntersect);
float3 furthestPlane = max(firstPlaneIntersect, secondPlaneIntersect);
float2 intersections;
// Find the furthest near intersection
intersections.x = max(closestPlane.x, max(closestPlane.y, closestPlane.z));
// Find the closest far intersection
intersections.y = min(min(furthestPlane.x, furthestPlane.y), furthestPlane.z);
return intersections;
}
// This simplified version assume that we care about the result only when we are inside the box
// Assume dir is normalize
float BoxRayIntersectSimple(float3 start, float3 dir, float3 boxMin, float3 boxMax)
{
float3 invDir = 1.0 / dir;
// Find the ray intersection with box plane
float3 rbmin = (boxMin - start) * invDir;
float3 rbmax = (boxMax - start) * invDir;
float3 rbminmax = (dir > 0.0) ? rbmax : rbmin;
return min(min(rbminmax.x, rbminmax.y), rbminmax.z);
}
// Assume Sphere is at the origin (i.e start = position - spherePosition)
float2 SphereRayIntersect(float3 start, float3 dir, float radius, out bool intersect)
{
float a = dot(dir, dir);
float b = dot(dir, start) * 2.0;
float c = dot(start, start) - radius * radius;
float discriminant = b * b - 4.0 * a * c;
float2 intersections = float2(0.0, 0.0);
intersect = false;
if (discriminant < 0.0 || a == 0.0)
{
intersections.x = 0.0;
intersections.y = 0.0;
}
else
{
float sqrtDiscriminant = sqrt(discriminant);
intersections.x = (-b - sqrtDiscriminant) / (2.0 * a);
intersections.y = (-b + sqrtDiscriminant) / (2.0 * a);
intersect = true;
}
return intersections;
}
// This simplified version assume that we care about the result only when we are inside the sphere
// Assume Sphere is at the origin (i.e start = position - spherePosition) and dir is normalized
// Ref: http://http.developer.nvidia.com/GPUGems/gpugems_ch19.html
float SphereRayIntersectSimple(float3 start, float3 dir, float radius)
{
float b = dot(dir, start) * 2.0;
float c = dot(start, start) - radius * radius;
float discriminant = b * b - 4.0 * c;
return abs(sqrt(discriminant) - b) * 0.5;
}
float3 RayPlaneIntersect(in float3 rayOrigin, in float3 rayDirection, in float3 planeOrigin, in float3 planeNormal)
{
float dist = dot(planeNormal, planeOrigin - rayOrigin) / dot(planeNormal, rayDirection);
return rayOrigin + rayDirection * dist;
}
//-----------------------------------------------------------------------------
// Miscellaneous functions
//-----------------------------------------------------------------------------
// Box is AABB
float DistancePointBox(float3 position, float3 boxMin, float3 boxMax)
{
return length(max(max(position - boxMax, boxMin - position), float3(0.0, 0.0, 0.0)));
}
float3 ProjectPointOnPlane(float3 position, float3 planePosition, float3 planeNormal)
{
return position - (dot(position - planePosition, planeNormal) * planeNormal);
}
// Plane equation: {(a, b, c) = N, d = -dot(N, P)}.
// Returns the distance from the plane to the point 'p' along the normal.
// Positive -> in front (above), negative -> behind (below).
float DistanceFromPlane(float3 p, float4 plane)
{
return dot(float4(p, 1.0), plane);
}
// Returns 'true' if the triangle is outside of the frustum.
// 'epsilon' is the (negative) distance to (outside of) the frustum below which we cull the triangle.
bool CullTriangleFrustum(float3 p0, float3 p1, float3 p2, float epsilon, float4 frustumPlanes[6], int numPlanes)
{
bool outside = false;
for (int i = 0; i < numPlanes; i++)
{
// If all 3 points are behind any of the planes, we cull.
outside = outside || Max3(DistanceFromPlane(p0, frustumPlanes[i]),
DistanceFromPlane(p1, frustumPlanes[i]),
DistanceFromPlane(p2, frustumPlanes[i])) < epsilon;
}
return outside;
}
// Returns 'true' if the edge of the triangle is outside of the frustum.
// The edges are defined s.t. they are on the opposite side of the point with the given index.
// 'epsilon' is the (negative) distance to (outside of) the frustum below which we cull the triangle.
bool3 CullTriangleEdgesFrustum(float3 p0, float3 p1, float3 p2, float epsilon, float4 frustumPlanes[6], int numPlanes)
{
bool3 edgesOutside = false;
for (int i = 0; i < numPlanes; i++)
{
bool3 pointsOutside = bool3(DistanceFromPlane(p0, frustumPlanes[i]) < epsilon,
DistanceFromPlane(p1, frustumPlanes[i]) < epsilon,
DistanceFromPlane(p2, frustumPlanes[i]) < epsilon);
// If both points of the edge are behind any of the planes, we cull.
edgesOutside.x = edgesOutside.x || (pointsOutside.y && pointsOutside.z);
edgesOutside.y = edgesOutside.y || (pointsOutside.x && pointsOutside.z);
edgesOutside.z = edgesOutside.z || (pointsOutside.x && pointsOutside.y);
}
return edgesOutside;
}
// Returns 'true' if a triangle defined by 3 vertices is back-facing.
// 'epsilon' is the (negative) value of dot(N, V) below which we cull the triangle.
// 'winding' can be used to change the order: pass 1 for (p0 -> p1 -> p2), or -1 for (p0 -> p2 -> p1).
bool CullTriangleBackFace(float3 p0, float3 p1, float3 p2, float epsilon, float3 viewPos, float winding)
{
float3 edge1 = p1 - p0;
float3 edge2 = p2 - p0;
float3 N = cross(edge1, edge2);
float3 V = viewPos - p0;
float NdotV = dot(N, V) * winding;
// Optimize:
// NdotV / (length(N) * length(V)) < Epsilon
// NdotV < Epsilon * length(N) * length(V)
// NdotV < Epsilon * sqrt(dot(N, N)) * sqrt(dot(V, V))
// NdotV < Epsilon * sqrt(dot(N, N) * dot(V, V))
return NdotV < epsilon * sqrt(dot(N, N) * dot(V, V));
}
#endif // UNITY_GEOMETRICTOOLS_INCLUDED